CN210453907U - Cross cutting thimble check out test set - Google Patents

Abstract

The utility model provides a die-cutting thimble detection device, which comprises an upper detection flat plate and a lower detection flat plate; a plurality of first sunken components and a plurality of second sunken components are arranged on the lower detection flat plate; the lower surface of the upper detection flat plate is provided with a first detection thimble and a second detection thimble; the first detection thimble is arranged above the first concave component, and the second detection thimble is arranged above the second concave component. And after the product paperboard after die cutting is placed on the lower detection flat plate, controlling the upper detection flat plate to move downwards. The first detection thimble continuously descends into the first concave component after abutting against the paper board, so that the paper boards on two sides of the notch are separated; meanwhile, the second detection thimble continues to descend to enter the second concave component after abutting against the paperboard, so that waste materials on the paperboard are removed. Based on this equipment, through the cross cutting effect to direct inspection cardboard after the cardboard cross cutting is accomplished, saved the trouble of artifical detection to greatly improved production efficiency.

Description

Cross cutting thimble check out test set

Technical Field

The utility model relates to an automation equipment technical field relates to a check out test set, especially a cross cutting thimble check out test set.

Background

When the paper box is produced, a flat paper board is generally subjected to die cutting, a plurality of product paper boards are cut according to a specific design, and an operator folds the product paper boards subjected to die cutting into a three-dimensional paper box.

Before folding into a carton, the operator needs to check whether the cuts are completely separated. If the die cutting effect is poor, when certain incisions of the product paperboard are still connected together, an operator needs to manually separate the incisions before folding into the paper box, but the manual separation incisions are likely to damage the product paperboard, so that defective products of the product paperboard are generated, and the paper box cannot be folded in later processes. Therefore, after die cutting is finished, the die cutting effect detection is an essential process.

The prior art generally examines the die cutting effect through manual detection, and specifically, an operator carefully performs visual inspection and separation operation on each cut on a product paperboard, namely, the condition of the cut is observed through visual inspection, and then the cut is separated through direct touch attempt. It is conceivable that the speed of die cutting is very fast, but the efficiency of manually checking the die cutting effect by an operator is very low, which severely limits the productivity. Therefore, the die cutting effect detection is a big bottleneck for improving the production efficiency of the paper box.

Accordingly, the prior art is yet to be improved and developed.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model lies in, to the above-mentioned defect of prior art, provide a cross cutting thimble check out test set, can realize automatic check cross cutting effect, greatly improved carton production efficiency.

The utility model provides a technical scheme that technical problem adopted as follows:

a die-cutting thimble detection device comprises an upper detection flat plate and a lower detection flat plate, wherein the upper detection flat plate and the lower detection flat plate are arranged along the horizontal direction, and the upper detection flat plate is arranged above the lower detection flat plate in a lifting manner;

the lower detection flat plate is provided with a plurality of first sunken components and a plurality of second sunken components;

the lower surface of the upper detection flat plate is provided with a first detection thimble and a second detection thimble, the first detection thimble and the second detection thimble are both perpendicular to the upper detection flat plate, the first detection thimble is used for separating paper plates on two sides of the notch by being matched with the first concave component, and the second detection thimble is used for removing waste materials on the paper plates by being matched with the second concave component;

the first detection thimble is arranged above the first concave component, and the second detection thimble is arranged above the second concave component.

Compared with the prior art, the beneficial effects of the technical scheme are that: and after the product paperboard after die cutting is placed on the lower detection flat plate, controlling the upper detection flat plate to move downwards. In the process that the upper detection panel runs downwards, the first detection thimble abuts against the paper board and then continues to downwards enter the first concave component, so that the paper boards on two sides of the notch are separated; meanwhile, the second detection thimble continues to descend to enter the second concave component after abutting against the paperboard, so that waste materials on the paperboard are removed. Based on this equipment, through the cross cutting effect to direct inspection cardboard after the cardboard cross cutting is accomplished, saved the trouble of artifical detection to greatly improved production efficiency.

Furthermore, how many inclined plates are nested in the lower detection flat plate, and the first concave component is a chute formed between each inclined plate and the upper surface of the lower detection flat plate; the plurality of inclined plates are arranged in an inclined manner towards the same direction;

the paper board enters from one side of the lower detection flat plate and exits from the other opposite side, the inclined plate is provided with an upper edge and a lower edge which are opposite, the horizontal height of the upper edge is higher than that of the lower edge, and the lower edge gradually inclines and upwards transits to the upper edge along the direction that the paper board exits from the lower detection flat plate.

The beneficial effect who adopts above-mentioned scheme is: the first concave component is used for reserving a certain space, and the first detection thimble can continuously descend after abutting against the paper board, so that the paper boards on two sides of the notch are separated; through setting up the hang plate, can form the chute as first sunk component between hang plate and lower detection flat board upper surface on the one hand, on the other hand can also be convenient for more detect the cardboard after accomplishing and withdraw from down and detect the flat board.

Furthermore, the second sunken component is a waste discharge through hole which is arranged on the lower detection flat plate in a penetrating manner.

The beneficial effect who adopts above-mentioned scheme is: a waste discharging through hole is formed in the lower detection flat plate and serves as a second sunken component, the second sunken component corresponds to the second detection thimble, and when the second detection thimble abuts against the paperboard, the second detection thimble can continuously downwards enter the waste discharging through hole, so that the second detection thimble forcibly downwards presses a part to be removed on the paperboard after die cutting, and waste on the paperboard is removed; the removed waste material falls down along the waste discharge through hole by gravity.

Furthermore, a plurality of inclined plates are sequentially arranged into an inclined plate column, and a plurality of inclined plate columns are arranged on the lower detection flat plate;

the waste discharge through holes are sequentially arranged into a through hole row, and the lower detection flat plate is provided with a plurality of through hole rows;

six inclined plate rows are arranged, namely a first inclined plate row, a second inclined plate row, a third inclined plate row, a fourth inclined plate row, a fifth inclined plate row and a sixth inclined plate row;

the number of the through hole rows is three, namely a first through hole row, a second through hole row and a third through hole row;

the first through hole row is arranged between the first inclined plate row and the second inclined plate row, the second through hole row is arranged between the third inclined plate row and the fourth inclined plate row, and the third through hole row is arranged between the fifth inclined plate row and the sixth inclined plate row;

a first blank area is formed between the second inclined plate array and the third inclined plate array, and a second blank area is formed between the fourth inclined plate array and the fifth inclined plate array;

go up the below that detects the flat board and be provided with a plurality of soft buffering subassemblies, soft buffering subassembly set up in first blank region with the corresponding top in second blank region.

The beneficial effect who adopts above-mentioned scheme is: on one hand, the soft buffer components are used for pressing the paper boards after die cutting on the lower detection flat plate, so that the paper boards are prevented from floating or being damaged; on the other hand, soft buffering subassembly sets up in the corresponding top in first blank region and second blank region, can guarantee that soft buffering subassembly and first detection thimble and second detect the thimble and stagger, do not influence the detection function.

Further, the soft buffer component is made of foam plastics or sponge.

The beneficial effect who adopts above-mentioned scheme is: the foam plastic or the sponge is adopted as the foam plastic or the sponge, and the structure is simple.

Furthermore, the lower end of the first detection thimble is of a flat-head structure, and the lower end of the second detection thimble is of a pointed-head structure.

The beneficial effect who adopts above-mentioned scheme is: the first detection thimble is used for separating the paper boards on two sides of the notch, and the lower end of the first detection thimble is arranged to be a flat-head structure, so that the paper boards can be protected from being damaged while the separation effect is achieved; the second detection thimble is used for removing waste materials on the paperboard, and the lower end of the second detection thimble is arranged to be a pointed structure which can intensively apply force to a waste material area, so that the waste materials are separated from the paperboard.

Further, the lower end of the first detection thimble is provided with a cushion.

The beneficial effect who adopts above-mentioned scheme is: the first detection thimble is prevented from damaging the paperboard through the buffering effect of the cushion.

Furthermore, the upper detection flat plate is of a hollow structure.

The beneficial effect who adopts above-mentioned scheme is: the weight of the upper detection flat plate is reduced, and the air resistance of the upper detection flat plate in the lifting process is reduced.

Further, the upper detection flat plate and the lower detection flat plate are bakelite.

The beneficial effect who adopts above-mentioned scheme is: the bakelite has the advantages of high strength, machine shaping and smooth surface.

Furthermore, the lower surface of the upper detection panel is provided with a plurality of mounting blind holes, and the upper ends of the first detection thimble and the second detection thimble are fixedly arranged on the lower surface of the upper detection panel by being closely matched with the mounting blind holes.

The beneficial effect who adopts above-mentioned scheme is: the device has the advantages of simple structure, convenience in installation and the like, and is more convenient for daily maintenance.

Drawings

Fig. 1 is the utility model relates to a cross cutting thimble check out test set's whole schematic diagram.

Fig. 2 is a schematic view of a portion of a paperboard detected by the die-cutting thimble detecting device of the present invention.

Fig. 3 is the utility model relates to a detect dull and stereotyped schematic diagram down in cross cutting thimble check out test set.

Figure 4 is the utility model relates to a detect dull and stereotyped local profile view down in cross cutting thimble check out test set.

Fig. 5 is a schematic diagram of an upper detection plate in the die-cutting thimble detection equipment.

Figure 6 is the utility model relates to an go up in cross cutting thimble check out test set and detect dull and stereotyped local profile view.

In the figures, the list of components represented by the various reference numbers is as follows:

an upper detection flat plate 1, a lower detection flat plate 2 and a unit paper plate 3;

a first detection thimble 11 and a second detection thimble 12;

a first concave component 21, a second concave component 22, an inclined plate 23, a first inclined plate column 24, a second inclined plate column 25, a third inclined plate column 26, a fourth inclined plate column 27, a fifth inclined plate column 28 and a sixth inclined plate column 29;

a separation site 31 and a waste site 32.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention will be described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it should be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or assembly referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may for example be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; the two components can be directly connected or indirectly connected through an intermediate medium, and the two components can be communicated with each other. When an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The specific meaning of the above terms in the present invention can be understood in specific cases for those skilled in the art.

When the paper box is produced, a flat paper board is generally subjected to die cutting, a plurality of product paper boards are cut according to a specific design, and an operator folds the product paper boards subjected to die cutting into a three-dimensional paper box.

Fig. 2 shows the blank after die cutting, in fig. 2, there are a total of three unit blanks 3, each unit blank 3 being foldable into a complete carton. And die cutting is carried out on the raw material paperboard, namely, the raw material paperboard is cut according to a specific shape through a cutter, so that the corresponding unit paperboard 3 is obtained.

On the paperboard in the die cutting process, a separation part 31 and a waste part 32 are formed, wherein the separation part 31 still has a place connected with the whole unit paperboard 3, only the paperboards at two sides of the cut are needed to be separated, the position corresponding to the dotted line in fig. 2 is the cut, and the two sides of the dotted line are the paperboards needed to be separated from each other; the waste portion 32 is a portion completely separated from the cardboard, and can be understood as a hole obtained by hollowing out a piece of cardboard. When the paper box is produced, a plurality of unit paper boards 3 can be obtained by die cutting according to the shape and specification of the paper box. Generally, the raw material paperboard is die-cut to obtain a product paperboard, and a plurality of unit paperboards 3 are correspondingly arranged side by side on one product paperboard.

Before folding into a carton, the operator needs to check whether the cuts are completely separated. On the one hand, it is necessary to detect whether the sheets on both sides of the slit can be separated from each other at the separation portion 31, i.e., whether the positions corresponding to the dotted lines in fig. 2 can be separated; on the other hand, it is necessary to check whether the waste is completely separated at the waste portion 32 to form a corresponding hole in the unit sheet.

The significance of cardboard detection lies in confirming whether the cardboard that detects the incision both sides can alternate segregation and the waste material can break away from completely, if lead to the adhesion because the cross cutting error, the in-process of follow-up paper folding box will tear easily and damage the cardboard, leads to the defective products. It will be appreciated that a product sheet will typically have a plurality of individual sheets 3 thereon, which is extremely inefficient if manually inspected by the prior art.

As shown in fig. 1, in order to solve the above problem, the utility model provides a cross cutting thimble check out test set specifically includes and detects dull and stereotyped 1 and detect dull and stereotyped 2 down, go up detect dull and stereotyped 1 with detect dull and stereotyped 2 along the horizontal direction setting down, go up detect dull and stereotyped 1 liftable set up in detect dull and stereotyped 2's top down.

As shown in fig. 1 and 2, a plurality of first concave components 21 and a plurality of second concave components 22 are arranged on the lower detection flat plate 2; correspondingly, as shown in fig. 5, a first detection thimble 11 and a second detection thimble 12 are disposed on the lower surface of the upper detection flat plate 1, the first detection thimble 11 and the second detection thimble 12 are both perpendicular to the upper detection flat plate 1, the first detection thimble 11 is configured to separate the paper boards at two sides of the notch by cooperating with the first concave component 21, and the second detection thimble 12 is configured to remove waste materials on the paper boards by cooperating with the second concave component 22; the first detecting thimble 11 is disposed above the first concave component 21, and the second detecting thimble 12 is disposed above the second concave component 22.

The specific working process of the equipment is as follows: after the raw sheet is die cut to obtain the product sheet, the product sheet is conveyed to the lower inspection plate 2, and when the product sheet is placed on the upper surface of the lower inspection plate 2, the separation portion 31 is located above the first recess assembly 21, and the waste portion 32 is located above the second recess assembly 22. Then, the upper detection flat plate 1 moves downwards, after the first detection thimble 11 and the second detection thimble 12 abut against the paper boards, the upper detection flat plate 1 keeps moving downwards continuously, and the first detection thimble 11 pushes the separation part 31 to enter the first concave component 21, so that the paper boards along the two sides of the notch can be separated from each other; at the same time, the second detection pin 12 presses the waste portion 32 into the second concave element 22, so that the waste can be completely separated from the cardboard. Correspondingly, a plurality of first detection thimbles 11 and a plurality of second detection thimbles 12 are arranged on the upper detection flat plate 1, and a plurality of first concave components 21 and a plurality of second concave components 22 are arranged on the lower detection flat plate 2, so that the detection of the whole product paperboard can be completed through one-time downward movement of the upper detection flat plate 1, and the production efficiency of the paperboard is greatly improved.

It should be noted that the utility model discloses a point lies in cross cutting thimble check out test set itself, and is not in the device of carrying the product cardboard, detect the device of dull and stereotyped motion on the device of specific position and the control of product cardboard location, and the technical scheme that can realize above-mentioned effect in prior art all can use the utility model discloses in.

As shown in fig. 3 and 4, how many inclined plates 23 are nested in the lower detection flat plate 2, and the first concave component 21 is a chute formed between the inclined plates 23 and the upper surface of the lower detection flat plate 2; the plurality of inclined plates 23 are inclined in the same direction.

The sheet enters from one side of the lower detection panel 2 and exits from the opposite side. As shown in fig. 4, the cardboard enters the lower detection plate 2 from the left side of fig. 4, the upper detection plate 1 is pressed downwards for detection, and the cardboard exits the lower detection plate 2 from the right side of fig. 4 after detection. In order to make the operation of this equipment more smooth and easy, the utility model discloses an innovation point lies in: the inclined plate 23 is provided with an upper edge and a lower edge which are opposite, the level of the upper edge is higher than that of the lower edge, and the lower edge gradually and obliquely transits upwards to the upper edge along the direction that the paper board exits the lower detection flat plate 2.

The specific working process is as follows: after entering from one side of the lower detection flat plate 2, the first detection thimble 11 presses the separation part 31 into a chute formed between the inclined plate 23 and the upper surface of the lower detection flat plate 2, so that the paper plates at two sides of the notch can be separated from each other. The separation portion 31 is pressed downward to be inclined downward at a certain angle and the downward inclination is maintained for a certain time, and after the upper sensing plate 1 is pressed downward to complete sensing, the sheet is withdrawn from the other side of the lower sensing plate 2.

If the inclined plate 23 is not provided and the inclined lower edge gradually and obliquely transitions upwards to the upper edge along the direction of the paper sheet exiting from the lower detection plate 2, but only a recess is provided in the lower detection plate 2 to provide a space for the first detection pin 11 to descend, the separation portion 31 is likely to be stuck in the first recess assembly 21 during the paper sheet exiting process after the detection is completed. By arranging the inclined plate 23, in the process that the paperboard exits from the lower detection flat plate 2, the downward-inclined separation part 31 can be gradually lifted along the direction from the lower edge to the upper edge of the inclined plate 23 and can move to the upper surface of the lower detection flat plate 2 from the inclined groove, so that the paperboard can be prevented from being clamped in the first concave component 21, and the paperboard after detection can be conveniently exited from the lower detection flat plate 2.

As shown in fig. 3, the second concave member 22 is a waste discharge through hole, and the waste discharge through hole is penetratingly disposed on the lower detection plate 2. A waste discharge through hole is formed in the lower detection flat plate 2 and serves as a second sunken component 22, the second sunken component 22 corresponds to the second detection thimble 12, and when the second detection thimble 12 abuts against the paperboard, the second detection thimble 12 can continuously downwards enter the waste discharge through hole, so that the second detection thimble 12 forcibly downwards presses a part to be removed on the paperboard after die cutting, and waste on the paperboard is removed; the removed waste material falls down along the waste discharge through hole by gravity.

As shown in fig. 3, a plurality of inclined plates 23 are sequentially arranged in an inclined plate row, and a plurality of inclined plate rows are arranged on the lower detection flat plate 2; the waste discharge through holes are sequentially arranged into a through hole row, and the lower detection flat plate 2 is provided with a plurality of through hole rows.

Specifically, the number of the inclined plate rows is six, namely a first inclined plate row 24, a second inclined plate row 25, a third inclined plate row 26, a fourth inclined plate row 27, a fifth inclined plate row 28 and a sixth inclined plate row 29; the number of the through hole rows is three, namely a first through hole row, a second through hole row and a third through hole row; the first through hole row is arranged between the first inclined plate row 24 and the second inclined plate row 25, the second through hole row is arranged between the third inclined plate row 26 and the fourth inclined plate row 27, and the third through hole row is arranged between the fifth inclined plate row 28 and the sixth inclined plate row 29; a first blank region is formed between the second and third oblique rows 25, 26, and a second blank region is formed between the fourth and fifth oblique rows 27, 28. Correspondingly, a plurality of soft buffer components are arranged below the upper detection flat plate 1, and the soft buffer components are arranged above the first blank area and the second blank area.

For the purpose of saving raw material cardboard, the raw material cardboard is die-cut by arranging the separation sites 31 and the waste sites 32 in a plurality of rows, respectively. Correspondingly, the specification sizes of the inclined plate columns and the through hole columns can be adaptively adjusted according to the specific specification sizes of the paper boxes. The specific embodiment of the utility model is provided with six inclined plate rows and three through hole rows, which are suitable for the size of the common cigarette paper box.

In the present technical solution, each inclined plate 23 is correspondingly provided with a first detection thimble 11, and each waste discharge through hole is correspondingly provided with a second detection thimble 12. In order to arrange a plurality of soft buffer components below the upper detection flat plate 1, since the corresponding upper portions of the first blank region and the second blank region are staggered from the first detection thimble 11 and the second detection thimble 12, preferably, the soft buffer components need to be arranged above the corresponding upper portions of the first blank region and the second blank region.

Therefore, the soft buffer component is arranged in this way, and the following effects can be brought: on one hand, the soft buffer components are used for pressing the paper boards after die cutting on the lower detection flat plate 2 to prevent the paper boards from floating or being damaged; on the other hand, soft buffer component sets up in the corresponding top in first blank region and second blank region, can guarantee that soft buffer component staggers with first detection thimble 11 and second detection thimble 12, does not influence the detection function.

Specifically, soft buffering subassembly passes through the lower surface of two-sided gluing laminating on detecting dull and stereotyped 1, soft buffering subassembly is foamed plastic or sponge, adopts foamed plastic or sponge as foamed plastic or sponge, has simple structure's advantage.

Preferably, a sponge is selected as the soft cushioning component. The sponge has the advantage of the light and on-stick cardboard of quality, on the one hand, can not increase the burden for the elevating movement who goes up to detect dull and stereotyped 1, and on the other hand, last detection dull and stereotyped 1 pushes down the back of detecting, can guarantee not to adhere on the cardboard.

Preferably, the lower end of the first detection pin 11 is configured as a flat-head structure, and the lower end of the second detection pin 12 is configured as a pointed-head structure. The first detection thimble 11 is used for separating paper boards on two sides of the notch, and the lower end of the first detection thimble 11 is arranged to be a flat-head structure, so that the paper boards can be protected from being damaged while the separation effect is achieved; the second detection thimble 12 is used for removing waste materials on the paper board, and the lower end of the second detection thimble 12 is arranged to be a pointed structure which can intensively apply force to a waste material area, so that the waste materials are separated from the paper board. Further preferably, a soft pad is further disposed at the lower end of the first detecting thimble 11. The first detection thimble 11 is prevented from damaging the paperboard by the buffering action of the soft pad.

Preferably, the upper detection plate 1 is a hollow structure. The upper detection flat plate 1 is arranged to be of a hollow structure, so that the weight of the upper detection flat plate 1 can be reduced, and the air resistance of the upper detection flat plate 1 in the lifting process is reduced. It should be noted that the hollowed-out portion needs to avoid the mounting positions of the first detecting pin 11, the second detecting pin 12 and the soft buffer component.

Preferably, the upper detection plate 1 and the lower detection plate 2 are bakelite. The bakelite has the advantages of high strength, machine shaping and smooth surface, is convenient to machine and manufacture to obtain the corresponding upper detection flat plate 1 and the lower detection flat plate 2, and is more favorable for preventing the paperboard product from being scratched in the processes of entering and exiting.

As shown in fig. 6, the lower surface of the upper detection plate 1 is provided with a plurality of mounting blind holes, and the upper ends of the first detection thimble 11 and the second detection thimble 12 are fixedly disposed on the lower surface of the upper detection plate 1 by being closely fitted with the mounting blind holes.

Besides the above installation manner, the first detecting thimble 11 and the second detecting thimble 12 can be installed by the following scheme: go up the lower surface that detects dull and stereotyped 1 and be provided with a plurality of internal screw holes, first detection thimble 11 with the upper end that the second detected thimble 12 is provided with external screw thread portion, first detection thimble 11 with the second detects thimble 12 and is fixed to be set up through the screw-thread fit of external screw thread portion with internal screw hole go up the lower surface that detects dull and stereotyped 1.

Through the installation of above two kinds of modes, first detection thimble 11 and second detection thimble 12 have advantages such as simple structure and simple to operate, and the daily maintenance of being convenient for more simultaneously can conveniently be changed when certain first detection thimble 11 or second detection thimble 12 goes wrong.

To sum up, the utility model provides a die-cutting thimble detection device, which comprises an upper detection flat plate and a lower detection flat plate, wherein the upper detection flat plate and the lower detection flat plate are arranged along the horizontal direction, and the upper detection flat plate is arranged above the lower detection flat plate in a liftable way; the lower detection flat plate is provided with a plurality of first sunken components and a plurality of second sunken components; the lower surface of the upper detection flat plate is provided with a first detection thimble and a second detection thimble, the first detection thimble and the second detection thimble are both perpendicular to the upper detection flat plate, the first detection thimble is used for separating paper plates on two sides of the notch by being matched with the first concave component, and the second detection thimble is used for removing waste materials on the paper plates by being matched with the second concave component; the first detection thimble is arranged above the first concave component, and the second detection thimble is arranged above the second concave component. Compared with the prior art, the beneficial effects of the technical scheme are that: and after the product paperboard after die cutting is placed on the lower detection flat plate, controlling the upper detection flat plate to move downwards. In the process that the upper detection panel runs downwards, the first detection thimble abuts against the paper board and then continues to downwards enter the first concave component, so that the paper boards on two sides of the notch are separated; meanwhile, the second detection thimble continues to descend to enter the second concave component after abutting against the paperboard, so that waste materials on the paperboard are removed. Based on this equipment, through the cross cutting effect to direct inspection cardboard after the cardboard cross cutting is accomplished, saved the trouble of artifical detection to greatly improved production efficiency.

It is to be understood that the invention is not limited to the above-described embodiments, and that modifications and variations may be made by those skilled in the art in light of the above teachings, and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims (10)

1. The utility model provides a cross cutting thimble check out test set which characterized in that: the device comprises an upper detection flat plate and a lower detection flat plate, wherein the upper detection flat plate and the lower detection flat plate are arranged along the horizontal direction, and the upper detection flat plate is arranged above the lower detection flat plate in a lifting manner;

the lower detection flat plate is provided with a plurality of first sunken components and a plurality of second sunken components;

the lower surface of the upper detection flat plate is provided with a first detection thimble and a second detection thimble, the first detection thimble and the second detection thimble are both perpendicular to the upper detection flat plate, the first detection thimble is used for separating paper plates on two sides of the notch by being matched with the first concave component, and the second detection thimble is used for removing waste materials on the paper plates by being matched with the second concave component;

the first detection thimble is arranged above the first concave component, and the second detection thimble is arranged above the second concave component.

2. The die-cutting ejector pin detection device of claim 1, wherein: the lower detection flat plate is internally provided with a plurality of inclined plates in an embedded mode, and the first concave component is an inclined groove formed between each inclined plate and the upper surface of the lower detection flat plate; the plurality of inclined plates are arranged in an inclined manner towards the same direction;

the paper board enters from one side of the lower detection flat plate and exits from the other opposite side, the inclined plate is provided with an upper edge and a lower edge which are opposite, the horizontal height of the upper edge is higher than that of the lower edge, and the lower edge gradually inclines and upwards transits to the upper edge along the direction that the paper board exits from the lower detection flat plate.

3. The die-cutting ejector pin detection device of claim 2, wherein: the second sunken component is a waste discharge through hole which is arranged on the lower detection flat plate in a penetrating manner.

4. The die-cutting ejector pin detection device of claim 3, wherein: the plurality of inclined plates are sequentially arranged into an inclined plate column, and the lower detection flat plate is provided with a plurality of inclined plate columns;

the waste discharge through holes are sequentially arranged into a through hole row, and the lower detection flat plate is provided with a plurality of through hole rows;

six inclined plate rows are arranged, namely a first inclined plate row, a second inclined plate row, a third inclined plate row, a fourth inclined plate row, a fifth inclined plate row and a sixth inclined plate row;

the number of the through hole rows is three, namely a first through hole row, a second through hole row and a third through hole row;

the first through hole row is arranged between the first inclined plate row and the second inclined plate row, the second through hole row is arranged between the third inclined plate row and the fourth inclined plate row, and the third through hole row is arranged between the fifth inclined plate row and the sixth inclined plate row;

a first blank area is formed between the second inclined plate array and the third inclined plate array, and a second blank area is formed between the fourth inclined plate array and the fifth inclined plate array;

go up the below that detects the flat board and be provided with a plurality of soft buffering subassemblies, soft buffering subassembly set up in first blank region with the corresponding top in second blank region.

5. The die-cutting ejector pin detection device of claim 4, wherein: the soft buffer component is made of foam plastics or sponge.

6. The die-cutting ejector pin detection device of claim 1, wherein: the lower end of the first detection thimble is of a flat-head-shaped structure, and the lower end of the second detection thimble is of a pointed-head-shaped structure.

7. The die-cutting ejector pin detection device of claim 6, wherein: the lower end of the first detection thimble is further provided with a soft pad.

8. The die-cutting ejector pin detection device of claim 1, wherein: the upper detection flat plate is of a hollow structure.

9. The die-cutting ejector pin detection device of claim 1, wherein: the upper detection flat plate and the lower detection flat plate are bakelite.

10. The die-cutting ejector pin detection device of claim 1, wherein: the lower surface of the upper detection panel is provided with a plurality of mounting blind holes, and the upper ends of the first detection thimble and the second detection thimble are fixedly arranged on the lower surface of the upper detection panel by being closely matched with the mounting blind holes.

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